A method for producing muscimol and or/reducing ibotenic acid from amanita tissue, and or producing a nutritional supplement therefrom.
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1. A method for producing a liquid dietary supplement from amanita tissue, the method comprising:
a. providing tissue comprising an amanita fungus comprising ibotenic acid within the tissue;
b. providing a reactant comprising an enzymatically effective amount of glutamate decarboxylase;
c. combining the tissue and reactant such that the ratio of muscimol to ibotenic acid increases; and
d. adding the reaction product of step (c) to a beverage to make the liquid dietary supplement.
12. A method for producing a liquid dietary supplement from amanita tissue, the method comprising:
a. providing tissue comprising an amanita fungus comprising ibotenic acid within the tissue;
b. comminuting and drying the tissue;
c. reconstituting the tissue of step (b);
d. subjecting the reconstituted tissue of step (c) to a ph below 4.5;
e. subjecting the reconstituted tissue of step (d) to heat above 175° F.; and
f. adding the reconstituted tissue of step (e) to a beverage to make the liquid dietary supplement.
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The present application discloses a method for producing muscimol and or/reducing ibotenic acid from Amanita tissue, and or producing a nutritional supplement therefrom.
Amanita muscaria, and closely related fungi (i.e., Amanita pantherina, Amanita muscaria variant formosa, and others within the Amanita genus) contain substances that are GABA analogues and antioxidants. For example, according to at least one study, Amanita species were found to have “the highest antioxidant activities” among mushroom species tested.1 However, when fresh tissue is ingested, even small amounts can cause symptoms of gastrointestinal distress (nausea, vomiting, diarrhea), headaches, profuse sweating, hypersalivation, periods of agitation and confusion, followed by coma-like sleep. These negative reactions are generally ascribed to the presence of ibotenic acid within fresh tissue, an excitatory neurotoxin. Although ibotenic acid is a neurotoxin with severe adverse effects at high concentrations, its decarboxylated variant, muscimol, is an analogue of gamma-aminobutyric acid (GABA). GABA and GABA analogues have many health benefits, including anti-aging properties, supporting the production of growth hormone, diuresis, neuroprotection, anti-hypertensive properties, and the promotion of healing.5,6,7
Fresh A. muscaria typically contains 258 to 471 ppm of ibotenic acid within the entirety of the fungi. Nearly all the ibotenic acid concentrated in the caps, and very little muscimol present.2 Typically, the ibotenic acid to muscimol ratio of fungal cap tissue would be 9:1 or greater in fresh samples.2 While drying of the fungal tissue has been reported to convert a portion of the ibotenic acid to muscimol, such conversion is incomplete and highly variable according to sample variation and conditions. Indeed, a relatively low conversion rate of only 30% is typical by merely drying fungal tissue, leaving an unacceptably high concentration of ibotenic acid, typically 180 to 1800 ppm.3,4 A common ibotenic acid to muscimol ratio would be 3:2 in dried specimens4, such that the neurotoxin amounts far exceed the GABA analogue. Furthermore, ingesting the dried tissue, which contains the relatively indigestible mushroom cell wall component chitin, would result in adverse physiological effects.
Therefore, a method to reduce the ibotenic acid in Amanita tissues, while maximizing water-soluble nutrients, including maximization of the GABA analogue muscimol, from a natural product, would be highly desirable.
According to certain embodiments, a method for producing a dietary supplement or beverage from Amanita tissue comprises providing tissue from an Amanita fungi comprising ibotenic acid within the tissue; providing a reactant comprising glutamate decarboxylase; combining the tissue and reactant such that the ratio of muscimol to ibotenic acid increases.
According to certain embodiments, the method further comprises comminuting and drying the Amanita tissue prior to combining the tissue and reactant. In certain additional embodiments, the method further comprises rehydrating the tissue prior to combining the tissue and reactant. Additionally, the method may further comprise heating the tissue and reactant to a temperature of at least 175° F. In certain additional embodiments, the method further comprises heating the tissue and reactant to a temperature of at least 175° F. for at least about one hour. According to certain embodiments, the method further includes reducing the pH of the tissue and reactant below 7.0.
The present disclosure relates to methods for producing a product having increased muscimol and/or ibotenic acid Amanita tissues (excluding Amanita phalloides and Amanita virosa). Additionally, according to certain embodiments, the present disclosure relates to products operable to act as nutritional supplements. According to one embodiment, an ingestible product is produced by the method of providing tissue from fungi. Specifically, tissue from an Amanita fungi is selected, preferably from the caps thereof. Thereafter, the tissue is optionally dried, freeze-dried, or otherwise dehydrated to approximately 0.3% to 5% water by weight. A distilled water extraction of the fresh or dried tissue is produced and filtered to produce a filtrate. After filtration, the filtrate is exposed to a pH above 8.0 or below 6.0, and is heated and/or refluxed for at least approximately one hour, and preferably approximately two hours, at a temperature of approximately 175° F.-200° F. Optionally, the filtrate is heated and/or refluxed at approximately 195° F.
In an alternative embodiment, the filtrate is exposed to purified glutamate decarboxylase, or a substance containing glutamate decarboxylase, and heated for 1 to 48 hours at a temperature of 90 degrees to 155 degrees F., at a pH of 3 to 6, with addition of pyridoxal 5 phosphate (“P-5-P”) as a cofactor, with or without the addition of calcium chloride, magnesium sulfate, or other ions.
In yet another alternative embodiment, the filtrate is combined with one or more Lactobacillus bacteria such as L plantarum, L. paracasei, L. lactis, L. brevei, L. delbrueckii, or any other fermenting bacteria containing glutamate decarboxylase, or a substance containing glutamate decarboxylase, such as rice bran. Thereafter, according to certain embodiments, the filtrate is optionally fermented with the bacteria. According to certain embodiments, the fermented product is filtered and clarified with or without pasteurization. According to at least one embodiment, the fermented product is filtered and clarified through cotton or other filtration material, and/or filtered through an activated carbon filter.
According to certain embodiments, the filtrate is combined with one or more Lactobacillus bacteria such as L plantarum, L. paracasei, L. lactis, L. brevei, L. delbrueckii, or any other bacteria known to contain glutamate decarboxylase (“GAD”). Thereafter, the filtrate and approximately 150,000 colony forming units (CFU's) of the bacteria per ounce of filtrate are optionally adjusted to a pH of 3.8-5.5 and incubated at a temperature of approximately 98°-155° F.
According to certain embodiments, approximately 0.4 g of CaCO3 or CaCl2 per 64 ounces of filtrate is added, along with a prescribed amount of P-5-P as a cofactor (typically 10 mg), and approximately 4.5 teaspoons of table sugar. Initial pH of the combination of the filtrate and bacteria is approximately 6, and typically drops rapidly within 12 to 24 hours of fermentation to just under a pH of 4. After approximately 3 days of fermentation, the product is filtered, refrigerated, and clarified. The fermented, filtered product is thereafter available for use.
Bioassays of the resultant product show acceptable taste, mouthfeel, and appearance, and may be mixed with fruit juice. The resultant product did not display the undesirable effects noted in fresh A. muscaria tissue.
According to one exemplary embodiment, Amanita tissue was manually cleaned to remove debris, and was thereafter shade-dried in a dehydrator for approximately 36 hours at 155 degrees F. Thereafter, the dried tissue was inspected after drying to verify it is dry to approximately 0.3% to 5% water by weight. The dried tissue was then ground to a fine powder using a bun grinder. A quantity of 300 grams or more was ground per batch, and placed in a single container capable of forming a hermetic seal.
Thereafter, the dried powder was stirred for 2 minutes, then shaken in the sealed container for approximately 2 minutes to ensure homogeneity of the sample and account for differences in sample tissues. Next, 60 grams of powder were combined with 60 ounces of cold, distilled water, in a container capable of forming a hermetic seal. The combined powder in aqueous solution was then placed in a refrigerator at approximately 42 degrees F. for about 5 days, with intermittent agitation to enhance the mixture of the contents. After 5 days, the contents were filtered by pouring through a cotton sieve sized sufficiently to remove all solids contained in the mixture. The solids were then discarded, and the filtrate was combined with additional distilled water sufficient to create a total of 60 ounces, as needed.
Next, approximately 10,000,000 CFU of Lactobacillus plantarum (showing glutamate decarboxylase), 0.4 gram of powdered calcium carbonate, 10 mg of pyridoxal-5-phosphate, and 4.5 teaspoons of table sugar were added to the 60 ounces of aqueous filtrate. This liquid was placed in a container capable of forming a hermetic seal, stirred, secured, and the contents agitated until thoroughly mixed. The initial pH of the combined solution was approximately 6.0. Thereafter, the combined filtrate was frozen until thoroughly solid. The frozen specimen was placed in an incubator at 103° degrees F. for 3 days. An additional 10,000,000 CFU of Lactobacillus plantarum was added at 12 hours into fermentation. After 18 hours of fermentation, the pH dropped to approximately 3.8-4.0, and remained stable for the duration of fermentation.
The fermentation process resulted in a change from a sweet flavor to a sour flavor of the liquid. The resulting product was once again is filtered through a cotton sieve, then finally filtered through a paper filter. Further clarification with diomataceous earth was utilized with the addition of one tablespoon of diomataceous earth to the liquid, allowing it to sit refrigerated for one week, then refiltering through cotton, then a paper filter.
Samples of Amanita muscaria var. formosa were dried in a dehydrator for 2 days at 125 degrees Fahrenheit. The caps were selected, ground to a powder, and mixed. 240 grams of powder was effused in 60 ounces of distilled water at 45 degrees Fahrenheit for 24 hours, then filtered to remove the solid particles. Thereafter, a portion of the filtrate was diluted by adding 0.75 cc distilled water per cc of filtrate, and set aside and frozen for later analysis. This portion was retained as an untreated, or control sample, referred in the accompanying table displayed in
Additionally, a second sample, “HCl” as shown in
Additionally, a third sample, “GAD” as shown in
The examples above were analyzed utilizing high performance liquid chromatography (“HPLC”), following derivatization using dansylation reaction.4 As can be seen from
It will be appreciated that the resulting converted product can be filtered utilizing activated carbon filters to remove nonpolar impurities, thereby improving purity and palatability of the resulting product.
Although the invention has been described in detail with reference to preferred embodiments, variations and modifications exist within the scope and spirit of the invention.
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